Your search keyword '"Simon N. Bland"' showing total 4 results

1. K-Edge Structure in Shock-Compressed Chlorinated Parylene

Author

David Bailie, Steven White, Rachael Irwin, Cormac Hyland, Richard Warwick, Brendan Kettle, Nicole Breslin, Simon N. Bland, David J. Chapman, Stuart P. D. Mangles, Rory A. Baggot, Eleanor R. Tubman, and David Riley

Subjects

ionization potential depression, continuum lowering, X-ray spectroscopy, Nuclear and particle physics. Atomic energy. Radioactivity, QC770-798

Abstract

We have carried out a series of experiments to measure the Cl K-absorption edge for shock-compressed samples of chlorinated parylene. Colliding shocks allowed us to compress samples up to four times the initial density with temperatures up to 10 eV. Red shifts in the edge of about 10 eV have been measured. We have compared the measured shifts to analytical modelling using the Stewart–Pyatt model and adaptions of it, combined with estimates of density and temperature based on hydrodynamic modelling. Modelling of the edge position using density functional theory molecular dynamics (DFT-MD) was also used and it was found that good agreement was only achieved when the DFT simulations assumed conditions of lower temperature and slightly higher density than indicated by hydrodynamic simulations using a tabular equation of state.

Published

2023

2. A Time-Resolved Imaging System for the Diagnosis of X-ray Self-Emission in High Energy Density Physics Experiments

Author

Jack W. D. Halliday, Simon N. Bland, Jack. D. Hare, Susan Parker, Lee G. Suttle, Danny R. Russell, Sergey V. Lebedev, U.S Department of Energy, and Defense Threat Reduction Agency

Subjects

Plasma Physics (physics.plasm-ph), 02 Physical Sciences, physics.plasm-ph, Computer Science::Computer Vision and Pattern Recognition, FOS: Physical sciences, 03 Chemical Sciences, Instrumentation, 09 Engineering, Physics - Plasma Physics, Applied Physics

Abstract

A diagnostic capable of recording spatially and temporally resolved x-ray self-emission data was developed to characterize experiments on the MAGPIE pulsed-power generator. The diagnostic used two separate imaging systems: a pinhole imaging system with two-dimensional spatial resolution and a slit imaging system with one-dimensional spatial resolution. The two-dimensional imaging system imaged light onto the image plate. The one-dimensional imaging system imaged light onto the same piece of image plate and a linear array of silicon photodiodes. This design allowed the cross-comparison of different images, allowing a picture of the spatial and temporal distribution of x-ray self-emission to be established. The design was tested in a series of pulsed-power-driven magnetic-reconnection experiments.

Published

2021

3. Modifying Wire Array Z-pinch Ablation Structure and Implosion Dynamics Using Coiled Arrays

Author

Gareth N. Hall, Simon N. Bland, Sergey V. Lebedev, Jeremy P. Chittenden, James B. A. Palmer, Francisco A. Suzuki-Vidal, George F. Swadling, Nicolas Niasse, P. F. Knapp, I. C. Blesener, R. D. McBride, D. A. Chalenski, K. S. Bell, J. B. Greenly, T. Blanchard, H. Wilhelm, D. A. Hammer, B. R. Kusse, Simon C. Bott, Bruce R. Kusse, and David A. Hammer

Subjects

Physics, Quantitative Biology::Biomolecules, business.industry, medicine.medical_treatment, Physics::Medical Physics, Implosion, Ablation, Magnetic field, Wavelength, Optics, Physics::Plasma Physics, Electromagnetic coil, Z-pinch, medicine, Magnetohydrodynamics, business, Axial symmetry

Abstract

Coiled arrays, a cylindrical array in which each wire is formed into a helix, suppress the modulation of ablation at the fundamental wavelength. Outside the vicinity of the wire cores, ablation flow from coiled arrays is modulated at the coil wavelength and has a 2‐stream structure in the r,θ plane. Within the vicinity of the helical wires, ablation is concentrated at positions with the greatest azimuthal displacement and plasma is axially transported from these positions such that the streams become aligned with sections of the coil furthest from the array axis. The GORGON MHD code accurately reproduces this observed ablation structure, which can be understood in terms of J×B forces that result from the interaction of the global magnetic field with a helical current path as well as additional current paths suggested by the simulations. With this ability to control where ablation streamers occur, large wavelength coils were constructed such that the breaks that form in the wires had sufficient axial separ...

Published

2009

4. Jet Deflection by a Quasi-Steady-State Side Wind in the Laboratory

Author

David J. Ampleford, Andrea Ciardi, Sergey V. Lebedev, Simon N. Bland, Simon C. Bott, Jeremy P. Chittenden, Gareth N. Hall, Adam Frank, and Eric Blackman

Published

2006